A transmitter circuit for use in a source synchronous type interface includes a flip-flop having a data input configured to receive serial data, a clock input configured to receive a source clock and a data output coupled to a data line. A first multiplexer has a first input configured to receive the source clock, a second input configured to receive a phase shifted clock (shifted by ninety degrees from the source clock), and a clock output coupled to a clock line. A control circuit operates to control selection by the first multiplexer of the source clock as a transmit clock sent over the clock line for a delay on clock at destination implementation. Alternatively, the control circuit causes selection by the first multiplexer of the phase shifted clock as the transmit clock sent over the clock line if the system is configured for a delay on clock at source implementation.

A system includes a controller for controlling communication between a first device and a second device connected by way of a communication interface. The controller that is associated with the first device is configured to receive a communication request from a processor of the first device for communicating with the second device. Based on the communication request, the controller is further configured to retrieve a set of instructions from an instruction memory that is associated with the first device. Further, the controller is configured to control the communication interface at each cycle of a clock signal by executing each instruction thus controlling the communication between the first and second devices at each cycle of the clock signal.

A machine automation system for controlling and operating an automated machine. The system includes a controller and sensor bus including a central processing core and a multi-medium transmission intranet for implementing a dynamic burst to broadcast transmission scheme where messages are burst from nodes to the central processing core and broadcast from the central processing core to all of the nodes.

Re-initialization of a link can take place without termination of the link, where the link includes, a transmitter and a receiver are to be coupled to each lane in the number of lanes, and re-initialization of the link is to include transmission of a pre-defined sequence on each of the lanes.

A storage controller communicates with an external device including a submission queue and a completion queue. An operation method of the storage controller includes receiving a notification associated with a command from the external device, based on a first clock, fetching the command from the submission queue, based on a second clock, performing an operation corresponding to the fetched command, based on a third clock, writing completion information to the completion queue, based on a fourth clock, and transmitting an interrupt signal to the external device, based on a fifth clock. Each of the first clock to the fifth clock is selectively activated depending on each operation phase.

An adapter is provided that includes a first interface to couple to a particular device, where link layer data is to be communicated over the first interface, and a second interface to couple to a physical layer (PHY) device. The PHY device includes wires to implement a physical layer of a link, and the link couples the adapter to another adapter via the PHY device. The second interface includes a data channel to communicate the link layer data over the physical layer, and a sideband channel to communicate sideband messages between the adapter and the other adapter over the physical layer. The adapter is to implement a logical PHY for the link.

A method for a slave device for calibrating an output timing for transmitting data to a master device is provided. The master and slave devices are communicatively coupled via an interface. The method includes: receiving, from the master device, one or more consecutive first signal edges indicating a synchronization event; recovering a reference clock of the master device based on the one or more consecutive first signal edges; transmitting one or more predetermined second signal edges to the master device and generated using the recovered reference clock; receiving, from the master device, data indicating one or more sampled values of the master device for the one or more predetermined second signal edges; and adjusting the output timing based on a comparison of the one or more predetermined second signal edges and the one or more sampled values of the master device for the one or more predetermined second signal edges.

A circuit for asynchronous data transfer includes a slave device having an asynchronous slave clock for transferring data to a master device having a master clock. The slave clock is a non-continuous clock signal. The slave device includes a clock detection circuit, a register bank, a temporary storage register, and a datapath selector. The slave device receives a data transfer command from the master device. The clock detection circuit detects a presence of the slave clock signal and generates a sync signal. To transfer the data to the master device, the datapath selector selects one of the temporary storage register and the register bank based on the sync signal. The slave device ensures seamless data transfer to the master device regardless of the presence or absence of the slave clock signal.

A physical layer (PHY) is coupled to a serial, differential link that is to include a number of lanes. The PHY includes a transmitter and a receiver to be coupled to each lane of the number of lanes. The transmitter coupled to each lane is configured to embed a clock with data to be transmitted over the lane, and the PHY periodically issues a blocking link state (BLS) request to cause an agent to enter a BLS to hold off link layer flit transmission for a duration. The PHY utilizes the serial, differential link during the duration for a PHY associated task selected from a group including an in-band reset, an entry into low power state, and an entry into partial width state

The present disclosure discloses a MIPI D-PHY circuit, which comprises a main control module, a controlled module, an internal data source generating module, and a configuration register. The main control module and the controlled module are respectively connected to the configuration register, and the main control module is connected to the internal data source generating module. The main control module and the controlled module comprise a clock channel and a data channel respectively. The clock channel and the data channel in the main control module and the data channel and the clock channel in the controlled module both comprise an error detection unit. The MIPI D-PHY circuit provided by the present disclosure adopts the error detection unit to detect the signals of the main control module and the controlled module, and the high-speed serial-parallel conversion and the high-speed parallel-serial conversion are realized by digital circuits, which reduces the area of the D-PHY circuit and reduces the complexity of the whole circuit.